15 results on '"Padmanabhan, Vasantha"'
Search Results
2. Sheep models of polycystic ovary syndrome phenotype.
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Padmanabhan, Vasantha and Veiga-Lopez, Almudena
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POLYCYSTIC ovary syndrome , *PHENOTYPES , *INFERTILITY , *REPRODUCTION , *METABOLIC disorders , *STEROIDS , *DISEASE susceptibility - Abstract
Abstract: Polycystic ovary syndrome (PCOS) is a fertility disorder affecting 5–7% of reproductive-aged women. Women with PCOS manifest both reproductive and metabolic defects. Several animal models have evolved, which implicate excess steroid exposure during fetal life in the development of the PCOS phenotype. This review addresses the fetal and adult reproductive and metabolic consequences of prenatal steroid excess in sheep and the translational relevance of these findings to PCOS. By comparing findings in various breeds of sheep, the review targets the role of genetic susceptibility to fetal insults. Disruptions induced by prenatal testosterone excess are evident at both the reproductive and metabolic level with each influencing the other thus creating a self-perpetuating vicious cycle. The review highlights the need for identifying a common mediator of the dysfunctions at the reproductive and metabolic levels and developing prevention and treatment interventions targeting all sites of disruption in unison for achieving optimal success. [Copyright &y& Elsevier]
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- 2013
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3. Prenatal testosterone excess programs reproductive and metabolic dysfunction in the female
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Padmanabhan, Vasantha, Manikkam, Mohan, Recabarren, Sergio, and Foster, Douglas
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TESTOSTERONE , *ESTROGEN , *ANDROGENS , *STEROIDS - Abstract
Abstract: Findings discussed in this review stress the importance of normal estrogen and androgen signaling at appropriate developmental time points in maintaining normal phenotypic expression, reproductive and metabolic function and document how inappropriate steroid signaling, at inopportune times can have undesirable outcomes. For example, inappropriate testosterone exposure during fetal life alters the developmental trajectory of the female culminating in a suite of disorders, which include intrauterine growth-retardation and postnatal catch up growth, phenotypic masculinization, reproductive neuroendocrine and ovarian disruptions leading to progressive loss of cyclicity and metabolic disruptions manifested as hyperinsulinemia. [Copyright &y& Elsevier]
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- 2006
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4. Neuroendocrine, autocrine, and paracrine control of follicle-stimulating hormone secretion.
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Padmanabhan, Vasantha and Cardoso, Rodolfo C.
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FOLLICLE-stimulating hormone , *SECRETION , *GLYCOPROTEIN hormones , *SHEEP , *ANIMAL models in research - Abstract
Follicle-stimulating hormone (FSH) is a glycoprotein hormone produced by gonadotropes in the anterior pituitary that plays a central role in controlling ovarian folliculogenesis and steroidogenesis in females. Moreover, recent studies strongly suggest that FSH exerts extragonadal actions, particularly regulating bone mass and adiposity. Despite its crucial role, the mechanisms regulating FSH secretion are not completely understood. It is evident that hypothalamic, ovarian, and pituitary factors are involved in the neuroendocrine, paracrine, and autocrine regulation of FSH production. Large animal models, such as the female sheep, represent valuable research models to investigate specific aspects of FSH secretory processes. This review: (i) summarizes the role of FSH controlling reproduction and other biological processes; (ii) discusses the hypothalamic, gonadal, and pituitary regulation of FSH secretion; (iii) considers the biological relevance of the different FSH isoforms; and (iv) summarizes the distinct patterns of FSH secretion under different physiological conditions. • FSH plays a key role in controlling ovarian folliculogenesis and steroidogenesis. • Hypothalamic, ovarian, and pituitary factors regulate FSH secretion. • The female sheep represents a valuable model to investigate FSH secretory processes. • Focusing on the sheep model, this review discusses the regulation of FSH secretion. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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5. Effect of maternal PCOS and PCOS-like phenotype on the offspring's health.
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Puttabyatappa, Muraly, Cardoso, Rodolfo C., and Padmanabhan, Vasantha
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POLYCYSTIC ovary syndrome , *PHENOTYPES , *INFANT health , *HYPERANDROGENISM , *ENDOCRINE system , *ANIMAL models in research , *ANDROGENS - Abstract
Polycystic ovary syndrome (PCOS) is a heterogeneous endocrine disorder with both reproductive and metabolic abnormalities affecting women of reproductive age. While the exact origin of PCOS is unknown, observations from clinical and animal studies suggest that maternal hyperandrogenism may be a contributing factor. Because women with PCOS manifest hyperandrogenism during pregnancy, changes in the gestational endocrine milieu may play a role in the vertical transmission of this syndrome. This review discusses the potential developmental origins of PCOS, the impact of maternal PCOS on the offspring's health and contributions of the postnatal environment, capitalizing on findings from animal models that exhibit a PCOS-like phenotype. In addition, this review highlights the scarcity of data at early gestational stages in humans and the importance of animal experimentation to better understand the cellular and molecular mechanisms involved in the programming of adult diseases, therefore, helping identify therapeutic targets for preventive and treatment strategies. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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6. Developmental programming: Testosterone excess masculinizes female pancreatic transcriptome and function in sheep.
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Halloran, Katherine M., Saadat, Nadia, Pallas, Brooke, Vyas, Arpita K., Sargis, Robert, and Padmanabhan, Vasantha
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POLYCYSTIC ovary syndrome , *TESTOSTERONE , *SHEEP , *INSULIN resistance , *FETUS , *ORGANIZATIONAL change , *ANDROGEN receptors , *HOMEOSTASIS - Abstract
Hyperandrogenic disorders, such as polycystic ovary syndrome, are often associated with metabolic disruptions such as insulin resistance and hyperinsulinemia. Studies in sheep, a precocial model of translational relevance, provide evidence that in utero exposure to excess testosterone during days 30–90 of gestation (the sexually dimorphic window where males naturally experience elevated androgens) programs insulin resistance and hyperinsulinemia in female offspring. Extending earlier findings that adverse effects of testosterone excess are evident in fetal day 90 pancreas, the end of testosterone treatment, the present study provides evidence that transcriptomic and phenotypic effects of in utero testosterone excess on female pancreas persist after cessation of treatment, suggesting lasting organizational changes, and induce a male-like phenotype in female pancreas. These findings demonstrate that the female pancreas is susceptible to programmed masculinization during the sexually dimorphic window of fetal development and shed light on underlying connections between hyperandrogenism and metabolic homeostasis. • Exposure to excess testosterone programs masculinization of female sheep pancreas. • Programming of beta-cell phenotype parallels transcriptomic masculinization. • Pancreatic alpha-cell phenotype is inconsistent with masculinization. • Fetal beta- and alpha-cell changes may underlie adverse adult pancreatic phenotype. [ABSTRACT FROM AUTHOR]
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- 2024
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7. Developmental programming: An exploratory analysis of pancreatic islet compromise in female sheep resulting from gestational BPA exposure.
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Ciarelli, Joseph, Thangaraj, Soundara Viveka, Sun, Haijing, Domke, Stephanie, Alkhatib, Bashar, Vyas, Arpita Kalla, Gregg, Brigid, Sargis, Robert M., and Padmanabhan, Vasantha
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ISLANDS of Langerhans , *ADULT children , *PANCREAS , *SHEEP , *ENDOCRINE disruptors , *PRENATAL exposure , *METABOLIC disorders - Abstract
Developmental exposure to endocrine disruptors like bisphenol A (BPA) are implicated in later-life metabolic dysfunction. Leveraging a unique sheep model of developmental programming, we conducted an exploratory analysis of the programming effects of BPA on the endocrine pancreas. Pregnant ewes were administered environmentally relevant doses of BPA during gestational days (GD) 30–90, and pancreata from female fetuses and adult offspring were analyzed. Prenatal BPA exposure induced a trend toward decreased islet insulin staining and β-cell count, increased glucagon staining and α-cell count, and increased α-cell/β-cell ratio. Findings were most consistent in fetal pancreata assessed at GD90 and in adult offspring exposed to the lowest BPA dose. While not assessed in fetuses, adult islet fibrosis was increased. Collectively, these data provide further evidence that early-life BPA exposure is a likely threat to human metabolic health. Future studies should corroborate these findings and decipher the molecular mechanisms of BPA's developmental endocrine toxicity. • Prenatal BPA programmed alterations in the endocrine pancreas of female sheep. • BPA reduced β-cell count, islet insulin in gestational day (GD) 90 fetal pancreata. • BPA increased α-cell count, size, α-to-β-cell ratio, islet glucagon in GD90 fetuses. • Low dose BPA increased islet glucagon, α-to-β-cell ratio, collagen in adult females. • Trends in elevated α-cell count, islet insulin and collagen seen in high BPA adults. [ABSTRACT FROM AUTHOR]
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- 2024
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8. Programming of GnRH feedback controls timing puberty and adult reproductive activity
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Foster, Douglas L., Jackson, Leslie M., and Padmanabhan, Vasantha
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ANDROGENS , *SEX hormones , *GERM cells ,SEX differences (Biology) - Abstract
Abstract: The timing of puberty generally differs between sexes, and this may be due to sex differences in the organization of steroid feedback systems. We propose that the reproductive neuroendocrine default sex is female. If the individual is male, the feedback control of GnRH secretion is programmed early in development, and the pubertal GnRH rise is either advanced or delayed depending upon species. This developmental programming is by androgens. Early programming also reorganizes adult reproductive neuroendocrine function to change a pattern of cyclic gamete release (periodic ovulations) requiring multiple feedback systems to that of a continuous one (spermatogenesis) requiring only the negative feedback control. The multiple feedback systems underlying the complex ovulatory cycle are innate, and in the male the unnecessary feedbacks are abolished or rendered less sensitive during development by the estrogenic, as well as the androgenic metabolites of testosterone. [Copyright &y& Elsevier]
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- 2006
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9. Developmental programming: Adipose depot-specific transcriptional regulation by prenatal testosterone excess in a sheep model of PCOS.
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Dou, John, Puttabyatappa, Muraly, Padmanabhan, Vasantha, and Bakulski, Kelly M.
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TESTOSTERONE regulation , *GENES , *FREE fatty acids , *RNA sequencing , *SHEEP , *ADIPOSE tissue physiology - Abstract
Prenatal testosterone (T)-treated female sheep manifest adipose depot-specific disruptions in inflammatory/oxidative state, adipocyte differentiation and thermogenic adipocyte distribution. The objective of this study was to identify common and divergent gene pathways underlying prenatal T excess-induced adipose depot-specific disruptions. RNA sequencing and network analyses were undertaken with visceral (VAT), subcutaneous (SAT), epicardiac (ECAT) and perirenal (PRAT) adipose tissues from control and prenatal T-treated (100 mg T propionate twice a week from days 30–90 of gestation) female sheep at 21 months of age. Increased expression of adiposity and inflammation-related genes in VAT and genes that promote differentiation of white adipocytes in SAT were congruous with their metabolic roles with SAT favoring uptake/storage of free fatty acids and triglycerides and VAT favoring higher rate of fatty acid turnover and lipolysis. Selective upregulation of cardiac muscle and renoprotection genes in ECAT and PRAT respectively are suggestive of protective paracrine actions. Expression profile in prenatal T-treated sheep paralleled depot-specific dysfunctions with increased proinflammatory genes in VAT, reduced adipocyte differentiation genes in VAT and SAT and increased vascular related gene expression in PRAT. The high expression of genes involved in cardiomyocyte function in ECAT is suggestive of cardioprotective function being maintained to overcome the prenatal T-induced cardiac dysfunction and hypertension. These findings coupled with changes in gene pathways and networks involved in chromatin modification, extracellular matrix, immune and mitochondrial function, and endoplasmic reticulum to Golgi transport suggest that dysregulation in gene expression underlie prenatal T-treatment induced functional differences among adipose depots and manifestation of metabolic dysfunction. Image 1 • Adult female sheep VAT, SAT, ECAT and PRAT depots showed distinct gene expression. • ECAT and PRAT expressed genes that influence cardiac and renal function, respectively. • Prenatal T excess reduced WAT differentiation genes distinctly in VAT and SAT. • Prenatal T excess increased cardiac muscle function-related genes in ECAT depots. • Prenatal T induced depot-specific chromatin/immune/mitochondrial/Golgi pathways. [ABSTRACT FROM AUTHOR]
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- 2021
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10. Placental single cell transcriptomics: Opportunities for endocrine disrupting chemical toxicology.
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Elkin, Elana R., Campbell, Kyle A., Lapehn, Samantha, Harris, Sean M., Padmanabhan, Vasantha, Bakulski, Kelly M., and Paquette, Alison G.
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TROPHOBLAST , *ENDOCRINE disruptors , *POISONS , *TOXICOLOGICAL chemistry , *FETAL growth retardation , *PLACENTA - Abstract
The placenta performs essential biologic functions for fetal development throughout pregnancy. Placental dysfunction is at the root of multiple adverse birth outcomes such as intrauterine growth restriction, preeclampsia, and preterm birth. Exposure to endocrine disrupting chemicals during pregnancy can cause placental dysfunction, and many prior human studies have examined molecular changes in bulk placental tissues. Placenta-specific cell types, including cytotrophoblasts, syncytiotrophoblasts, extravillous trophoblasts, and placental resident macrophage Hofbauer cells play unique roles in placental development, structure, and function. Toxicant-induced changes in relative abundance and/or impairment of these cell types likely contribute to placental pathogenesis. Although gene expression insights gained from bulk placental tissue RNA-sequencing data are useful, their interpretation is limited because bulk analysis can mask the effects of a chemical on individual populations of placental cells. Cutting-edge single cell RNA-sequencing technologies are enabling the investigation of placental cell-type specific responses to endocrine disrupting chemicals. Moreover, in situ bioinformatic cell deconvolution enables the estimation of cell type proportions in bulk placental tissue gene expression data. These emerging technologies have tremendous potential to provide novel mechanistic insights in a complex heterogeneous tissue with implications for toxicant contributions to adverse pregnancy outcomes. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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11. Developmental programming: Adipose depot-specific regulation of non-coding RNAs and their relation to coding RNA expression in prenatal testosterone and prenatal bisphenol-A -treated female sheep.
- Author
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Dou, John, Thangaraj, Soundara Viveka, Puttabyatappa, Muraly, Elangovan, Venkateswaran Ramamoorthi, Bakulski, Kelly, and Padmanabhan, Vasantha
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GENE expression , *NON-coding RNA , *RNA regulation , *BISPHENOL A , *TESTOSTERONE , *ESTROGEN receptors , *ADIPOGENESIS - Abstract
Inappropriate developmental exposure to steroids is linked to metabolic disorders. Prenatal testosterone excess or bisphenol A (BPA, an environmental estrogen mimic) leads to insulin resistance and adipocyte disruptions in female lambs. Adipocytes are key regulators of insulin sensitivity. Metabolic tissue-specific differences in insulin sensitivity coupled with adipose depot-specific changes in key mRNAs, were previously observed with prenatal steroid exposure. We hypothesized that depot-specific changes in the non-coding RNA (ncRNA) - regulators of gene expression would account for the direction of changes seen in mRNAs. Non-coding RNA (lncRNA, miRNA, snoRNA, snRNA) from various adipose depots of prenatal testosterone and BPA-treated animals were sequenced. Adipose depot-specific changes in the ncRNA that are consistent with the depot-specific mRNA expression in terms of directionality of changes and functional implications in insulin resistance, adipocyte differentiation and cardiac hypertrophy were found. Importantly, the adipose depot-specific ncRNA changes were model-specific and mutually exclusive, suggestive of different regulatory entry points in this regulation. [Display omitted] • Prenatal testosterone (T) excess programs adipose depot-specific changes in ncRNA. • Prenatal T induced ECAT miRNA changes is consistent with its cardioprotective role. • Prenatal T induced VAT ncRNA changes link to metabolism regulating coding genes. • Prenatal bisphenol A (BPA) programmed ncRNA changes was specific to VAT not SAT. • ncRNA changes in pre-T and BPA models indicate different mechanisms of action. [ABSTRACT FROM AUTHOR]
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- 2023
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12. Developmental programming: Metabolic tissue-specific changes in endoplasmic reticulum stress, mitochondrial oxidative and telomere length status induced by prenatal testosterone excess in the female sheep.
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Puttabyatappa, Muraly, Ciarelli, Joseph N., Chatoff, Adam G., and Padmanabhan, Vasantha
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ENDOPLASMIC reticulum , *MITOCHONDRIA , *TESTOSTERONE , *CELLULAR aging , *INSULIN sensitivity , *ADIPOSE tissue physiology , *TELOMERES - Abstract
Prenatal testosterone (T) excess-induced metabolic dysfunctions involve tissue specific changes in insulin sensitivity with insulin resistant, oxidative and lipotoxic state in liver/muscle and insulin sensitive but inflammatory and oxidative state in visceral adipose tissues (VAT). We hypothesized that mitochondrial dysfunction, endoplasmic reticulum (ER) stress and premature cellular senescence are contributors to the tissue-specific changes in insulin sensitivity. Markers of mitochondrial number, function, and oxidative phosphorylation (OxPhos), ER stress and cellular senescence (telomere length) were assessed in liver, muscle and 4 adipose (VAT, subcutaneous [SAT], epicardiac [ECAT] and perirenal [PRAT]) depots collected from control and prenatal T-treated female sheep at 21 months of age. Prenatal T treatment led to: (a) reduction in mitochondrial number and OxPhos complexes and increase in ER stress markers in muscle; (b) increase in fibrosis with trend towards increase in short telomere fragments in liver (c) depot-specific mitochondrial changes with OxPhos complexes namely increase in SAT and reduction in PRAT and increase in mitochondrial number in ECAT; (d) depot-specific ER stress marker changes with increase in VAT, reduction in SAT, contrasting changes in ECAT and no changes in PRAT; and (d) reduced shorter telomere fragments in SAT, ECAT and PRAT. These changes indicate insulin resistance may be driven by mitochondrial and ER dysfunction in muscle, fibrosis and premature senescence in liver, and depot-specific changes in mitochondrial function and ER stress without involving cellular senescence in adipose tissue. These findings provide mechanistic insights into pathophysiology of metabolic dysfunction among female offspring from hyperandrogenic pregnancies. [Display omitted] • Prenatal T excess induced fibrosis and telomere shortening in liver. • Prenatal T excess induced mitochondrial dysfunction and ER stress in muscle. • Prenatal T excess induced depot-specific mitochondrial, ER and telomere changes. • Prenatal T increased ER stress in VAT while reducing it in SAT. • Prenatal T improved mitochondrial function reduced telomere shortening in SAT/ECAT. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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13. Developmental programming: Prenatal testosterone excess disrupts pancreatic islet developmental trajectory in female sheep.
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Jackson, Ian J., Puttabyatappa, Muraly, Anderson, Miranda, Muralidharan, Meha, Veiga-Lopez, Almudena, Gregg, Brigid, Limesand, Sean, and Padmanabhan, Vasantha
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PANCREATIC beta cells , *HYPERINSULINISM , *ISLANDS of Langerhans , *SHEEP , *INSULIN resistance , *TESTOSTERONE , *GESTATIONAL age - Abstract
Prenatal testosterone (T)- treated female sheep manifest juvenile insulin resistance, post-pubertal increase in insulin sensitivity and return to insulin resistance during adulthood. Since compensatory hyperinsulinemia is associated with insulin resistance, altered pancreatic islet ontogeny may contribute towards metabolic defects. To test this, pregnant sheep were treated with or without T propionate from days 30–90 of gestation and pancreas collected from female fetuses at gestational day 90 and female offspring at 21 months-of-age. Uterine (maternal) and umbilical (fetal) arterial blood insulin/glucose ratios were determined at gestational day 90. The morphological and functional changes in pancreatic islet were assessed through detection of 1) islet hormones (insulin, glucagon) and apoptotic beta cells at fetal day 90 and 2) islet hormones (insulin, glucagon and somatostatin), and pancreatic lipid and collagen accumulation in adults. At gestational day 90, T-treatment led to maternal but not fetal hyperinsulinemia, decrease in pancreatic/fetal weight ratio and alpha cells, and a trend for increase in beta cell apoptosis in fetal pancreas. Adult prenatal T-treated female sheep manifested 1) significant increase in beta cell size and a tendency for increase in insulin and somatostatin stained area and proportion of beta cells in the islet; and 2) significant increase in pancreatic islet collagen and a tendency towards increased lipid accumulation. Gestational T-treatment induced changes in pancreatic islet endocrine cells during both fetal and adult ages track the trajectory of hyperinsulinemic status with the increase in adult pancreatic collagen accumulation indicative of impending beta cell failure with chronic insulin resistance. Image 1 • Gestational T excess induces maternal but not fetal hyperinsulinemia. • Gestational T excess reduced pancreatic/fetal weight ratio and fetal islet α cells. • Prenatal T-excess increased β cell size and collagen content. • Prenatal T excess tended to increase β cell number islet insulin and lipid content. • Prenatal T excess-induced islet disruptions contribute to hyperinsulinemia. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
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14. Developmental programming: Prenatal testosterone-induced changes in epigenetic modulators and gene expression in metabolic tissues of female sheep.
- Author
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Guo, Xingzi, Puttabyatappa, Muraly, Domino, Steven E., and Padmanabhan, Vasantha
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GENE expression , *ADIPOSE tissues , *SHEEP , *HISTONE acetylation , *INSULIN resistance , *TISSUES , *LIPID metabolism - Abstract
Prenatal testosterone (T)-treated female sheep manifest peripheral insulin resistance and tissue-specific changes in insulin sensitivity with liver and muscle manifesting insulin resistance accompanied by inflammatory, oxidative and lipotoxic state. In contrast, visceral (VAT) and subcutaneous (SAT) adipose tissues are insulin sensitive in spite of VAT manifesting changes in inflammatory and oxidative state. We hypothesized that prenatal T-induced changes in tissue-specific insulin resistance arise from disrupted lipid storage and metabolism gene expression driven by changes in DNA and histone modifying enzymes. Changes in gene expression were assessed in liver, muscle and 4 adipose (VAT, SAT, epicardiac [ECAT] and perirenal [PRAT]) depots collected from control and prenatal T-treated female sheep. Prenatal T-treatment increased lipid droplet and metabolism genes PPARA and PLIN1 in liver, SREBF and PLIN1 in muscle and showed a trend for decrease in PLIN2 in PRAT. Among epigenetic modifying enzymes, prenatal T-treatment increased expression of 1) DNMT1 in liver and DNMT3A in VAT, PRAT, muscle and liver; 2) HDAC1 in ECAT, HDAC2 in muscle with decrease in HDAC3 in VAT; 3) EP300 in VAT and ECAT; and 4) KDM1A in VAT with increases in liver histone acetylation. Increased lipid storage and metabolism genes in liver and muscle are consistent with lipotoxicity in these tissues with increased histone acetylation likely contributing to increased liver PPARA. These findings are suggestive that metabolic defects in prenatal T-treated sheep may arise from changes in key genes mediated, in part, by tissue-specific changes in epigenetic-modifying enzymes. Image 1 • Prenatal T induces tissue-specific changes in genes involved in lipid metabolism. • Prenatal T induces tissue-specific changes in genes involved in lipid storage. • Prenatal T induces tissue-specific changes in DNA and histone modifying enzymes. • Epigenetic enzyme changes may underlie tissue-specific metabolic changes. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
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15. Developmental programming: Adipose depot-specific changes and thermogenic adipocyte distribution in the female sheep.
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Puttabyatappa, Muraly, Ciarelli, Joseph N., Chatoff, Adam G., Singer, Kanakadurga, and Padmanabhan, Vasantha
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BROWN adipose tissue , *ADIPOGENESIS , *INSULIN resistance , *FAT cells , *ADIPOSE tissues , *SHEEP , *OXIDATIVE stress - Abstract
Prenatal testosterone (T)-treated female sheep exhibit an enhanced inflammatory and oxidative stress state in the visceral adipose tissue (VAT) but not in the subcutaneous (SAT), while surprisingly maintaining insulin sensitivity in both depots. In adult sheep, adipose tissue is predominantly composed of white adipocytes which favor lipid storage. Brown/beige adipocytes that make up the brown adipose tissue (BAT) favor lipid utilization due to thermogenic uncoupled protein 1 expression and are interspersed amidst white adipocytes, more so in epicardiac (ECAT) and perirenal (PRAT) depots. The impact of prenatal T-treatment on ECAT and PRAT depots are unknown. As BAT imparts a metabolically healthy phenotype, the depot-specific impact of prenatal T-treatment on inflammation, oxidative stress, differentiation and insulin sensitivity could be dictated by the distribution of brown adipocytes. This hypothesis was tested by assessing markers of oxidative stress, inflammation, adipocyte differentiation, fibrosis and thermogenesis in adipose depots from control and prenatal T (100 mg T propionate twice a week from days 30–90 of gestation) -treated female sheep at 21 months of age. Our results show prenatal T-treatment induces depot-specific changes in inflammation, oxidative stress state, collagen accumulation, and differentiation with changes being more pronounced in the VAT. Prenatal T-treatment also increased thermogenic gene expression in all depots indicative of increased browning with effects being more prominent in VAT and SAT. Considering that inflammatory and oxidative stress are also elevated, the increased brown adipocyte distribution is likely a compensatory response to maintain insulin sensitivity and function of organs in the proximity of respective depots. • Prenatal testosterone excess programs adipose depot-specific changes. • Depot-specific changes include negative/positive mediators of insulin sensitivity. • Prenatal testosterone excess increases thermogenic markers in all adipose depots. • Increase in thermogenesis may underlie preserved VAT and SAT insulin sensitivity. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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